Research Article
Open Access
Second-Order Boundary Value Problem with Integral Boundary Conditions
- Mouffak Benchohra1Email author,
- JuanJ Nieto2 and
- Abdelghani Ouahab1
Boundary Value Problems20102011:260309
https://doi.org/10.1155/2011/260309
© Mouffak Benchohra et al. 2011
Received: 28 May 2010
Accepted: 1 October 2010
Published: 13 October 2010
Abstract
The nonlinear alternative of the Leray Schauder type and the Banach contraction principle are used to investigate the existence of solutions for second-order differential equations with integral boundary conditions. The compactness of solutions set is also investigated.
1. Introduction
This paper is concerned with the existence of solutions for the second-order boundary value problem
(1.1)
where
is a given function and
is an integrable function.
Boundary value problems with integral boundary conditions constitute a very interesting and important class of problems. They include two, three, multipoint, and nonlocal boundary value problems as special cases. For boundary value problems with integral boundary conditions and comments on their importance, we refer the reader to the papers [1–9] and the references therein. Moreover, boundary value problems with integral boundary conditions have been studied by a number of authors, for example [10–14]. The goal of this paper is to give existence and uniqueness results for the problem (1.1). Our approach here is based on the Banach contraction principle and the Leray-Schauder alternative [15].
2. Preliminaries
In this section, we introduce notations, definitions, and preliminary facts that will be used in the remainder of this paper. Let
be the space of differentiable functions
whose first derivative,
, is absolutely continuous.
We take
to be the Banach space of all continuous functions from
into
with the norm
to be the Banach space of all continuous functions from
into
with the norm
(2.1)
and we let
denote the Banach space of functions
that are Lebesgue integrable with norm
denote the Banach space of functions
that are Lebesgue integrable with norm
(2.2)
Definition 2.1.
A map
is said to be
-Carathéodory if
(i)
is measurable for each
(ii)
is continuous for almost each
(iii)for every
there exists
such that
(2.3)
3. Existence and Uniqueness Results
Definition 3.1.
A function
is said to be a solution of (1.1) if
satisfies (1.1).
In what follows one assumes that
One needs the following auxiliary result.
Lemma 3.2.
. Let
. Then the function defined by
. Then the function defined by
(3.1)
is the unique solution of the boundary value problem
(3.2)
where
(3.3)
Proof.
Let
be a solution of the problem (3.2). Then integratingly, we obtain
be a solution of the problem (3.2). Then integratingly, we obtain
(3.4)
Hence
(3.5)
(3.6)
where
(3.7)
Now, multiply (3.6) by
and integrate over
, to get
and integrate over
, to get
(3.8)
Thus,
(3.9)
Substituting in (3.6) we have
(3.10)
Therefore
(3.11)
Set
Note that
Note that
(3.12)
Our first result reads
Theorem 3.3.
Assume that
is an
-Carathéodory function and the following hypothesis
(A1) There exists
such that
such that
(3.13)
holds. If
(3.14)
then the BVP (1.1) has a unique solution.
Proof.
Transform problem (1.1) into a fixed-point problem. Consider the operator
defined by
defined by
(3.15)
We will show that
is a contraction. Indeed, consider
Then we have for each
is a contraction. Indeed, consider
Then we have for each
(3.16)
Therefore
(3.17)
showing that,
is a contraction and hence it has a unique fixed point which is a solution to (1.1). The proof is completed.
We now present an existence result for problem (1.1).
Theorem 3.4.
Suppose that hypotheses
(H1) The function
is an
-Carathéodory,
(H2) There exist functions
and
such that
and
such that
(3.18)
are satisfied. Then the BVP (1.1) has at least one solution. Moreover the solution set
(3.19)
is compact.
Proof.
Transform the BVP (1.1) into a fixed-point problem. Consider the operator
as defined in Theorem 3.3. We will show that
satisfies the assumptions of the nonlinear alternative of Leray-Schauder type. The proof will be given in several steps.
Step 1 (
is continuous).
Let
be a sequence such that
in
Then
be a sequence such that
in
Then
(3.20)
Since
is
-Carathéodory and
then
is
-Carathéodory and
then
(3.21)
Hence
(3.22)
Step 2 (
maps bounded sets into bounded sets in
).
Indeed, it is enough to show that there exists a positive constant
such that for each
one has
.
Let
. Then for each
, we have
. Then for each
, we have
(3.23)
By (H2) we have for each
(3.24)
Then for each
we have
we have
(3.25)
Step 3 (
maps bounded set into equicontinuous sets of
).
Let
,
and
be a bounded set of
as in Step 2. Let
and
we have
,
and
be a bounded set of
as in Step 2. Let
and
we have
(3.26)
As
the right-hand side of the above inequality tends to zero. Then
is equicontinuous. As a consequence of Steps 1 to 3 together with the Arzela-Ascoli theorem we can conclude that
is completely continuous.
Step 4 (A priori bounds on solutions).
Let
for some
. This implies by
that for each
we have
for some
. This implies by
that for each
we have
(3.27)
Then
(3.28)
If
we have
we have
(3.29)
Thus
(3.30)
Hence
(3.31)
Set
(3.32)
and consider the operator
From the choice of
, there is no
such that
for some
As a consequence of the nonlinear alternative of Leray-Schauder type [15], we deduce that
has a fixed point
in
which is a solution of the problem (1.1).
Now, prove that
is compact. Let
be a sequence in
, then
is compact. Let
be a sequence in
, then
(3.33)
As in Steps 3 and 4 we can easily prove that there exists
such that
such that
(3.34)
and the set
is equicontinuous in
hence by Arzela-Ascoli theorem we can conclude that there exists a subsequence of
converging to
in
Using that fast that
is an
-Carathédory we can prove that
is equicontinuous in
hence by Arzela-Ascoli theorem we can conclude that there exists a subsequence of
converging to
in
Using that fast that
is an
-Carathédory we can prove that
(3.35)
Thus
is compact.
4. Examples
We present some examples to illustrate the applicability of our results.
Example 4.1.
Consider the following BVP
(4.1)
Set
(4.2)
We can easily show that conditions (A1), (3.14) are satisfied with
(4.3)
Hence, by Theorem 3.3, the BVP (4.1) has a unique solution on
.
Example 4.2.
Consider the following BVP
(4.4)
Set
(4.5)
We can easily show that conditions (H1), (H2) are satisfied with
(4.6)
Hence, by Theorem 3.4, the BVP (4.4) has at least one solution on
. Moreover, its solutions set is compact.
Declarations
Acknowledgment
The authors are grateful to the referees for their remarks.
Authors’ Affiliations
(1)
Department of Mathematics, University of Sidi Bel Abbes
(2)
Departamento de Análisis Matemático, Facultad de Matemáticas, Universidad de Santiago de Compostela
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© Mouffak Benchohra et al. 2011
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